Background independent quantum field theory and gravitating vacuum fluctuations

Abstract: The scale dependent effective average action for quantum gravity complies with the fundamental principle of Background Independence. Ultimately the background metric it formally depends on is selected self-consistently by means of a tadpole condition, a generalization of Einstein's equation. Self-consistent backround spacetimes are scale dependent, and therefore "going on-shell" at the points along a given renormalization group (RG) trajectory requires understanding two types of scale dependencies: the (famili… Show more

“…which is nothing but the first equation (1). At one-loop, and at the first order in , the non-Gaussian fixed point (4) is then compatible with the Ward identities.…”

“…Group field theories (GFTs) are a type of non-local fields theories defined on d-copies of a group manifold. From more than one decade, they have been considered as a promising way to quantize gravity [1]- [6]. A well defined theory for quantum gravity is necessary to understand the nature of space, time and geometry, and especially to address the questions about the origins of our universe.…”

Ward-constrained melonic renormalization group flow for the rank-four ϕ6 tensorial group field theory

“…which is nothing but the first equation (1). At one-loop, and at the first order in , the non-Gaussian fixed point (4) is then compatible with the Ward identities.…”

“…Group field theories (GFTs) are a type of non-local fields theories defined on d-copies of a group manifold. From more than one decade, they have been considered as a promising way to quantize gravity [1]- [6]. A well defined theory for quantum gravity is necessary to understand the nature of space, time and geometry, and especially to address the questions about the origins of our universe.…”

Ward-constrained melonic renormalization group flow for the rank-four ϕ6 tensorial group field theory

“…As a self-consistent truncation scheme appears to be available for quantum gravity, the apparent convergence of fixed-point results is a key goal. It is fair to say that the status of results is rather encouraging with regard to this question, see [91,118,119,124,125,132,175,[185][186][187][188][189][190][191][192][193][194][195][196][197][198][199][200]. This has given rise to the general expectation that the Reuter fixed point indeed exists in full theory space, and provides a universality class for quantum gravity.…”

“…In practice, the solutions of the Ward identity has only been possible for the simplest approximations [108,155,[203][204][205][206]. (3) When Ŵ k and with it (ḡ sc k ) µν show a strong k dependence, the effective spacetime is likely to possess multi-fractal properties which were argued to lead to a dimensional reduction in the ultraviolet [133,[208][209][210] and to a "fuzzy" spacetime structure at even lower scales [198,211,212]. In the existing analyses the fractal-like properties were characterized in terms of ordinary, i.e., smooth classical metrics, the trick being that one and the same spacetime manifold was equipped not with one but rather the one-parameter family of classical metrics, {(ḡ sc k ) µν }.…”

“…Moreover, the importance of properly accounting for the (k-dependent) ground state in studies of the flow is emphasized in a recent background-independent re-analysis of the cosmological constant problem allegedly caused by quantum vacuum fluctuations. Paying careful attention to identifying the correct ground state, the often discussed naturalness problem disappears, see [198].…”

Critical Reflections on Asymptotically Safe Gravity

The Functional Renormalization Group in Quantum Gravity